AU3946597A

AU3946597A - Idler roller

Info

Publication number: AU3946597A
Application number: AU39465/97A
Authority: AU
Inventors: Arend Jacobus Brink; Alan Habberley
Original assignee: Flow Handling Pty Ltd
Current assignee: Flow Handling Pty Ltd
Priority date: 1996-08-08
Filing date: 1997-08-07
Publication date: 1998-03-06
Anticipated expiration: 2017-08-07
Also published as: EP0928276A1; EP0928276B1; WO1998006649A1; US6148986A; DE69708312D1; AU723145B2; CN1237140A

Description

IDLER ROLLER

Field of the Invention

This invention relates to an idler roller, a method of constructing an idler roller and to an end cap for an idler roller.

Summary of the Invention

According to the invention there is provided an idler roller comprising an idler shell, a stub axle at each end of the idler shell and at least one bearing located on each stub axle rotatably supporting the idler shell.

In a further aspect of the invention there is provided an idler roller, comprising an end cap at each end of the idler shell, each of said end caps having a first component which is engageable with the idler shell, an inner cover and an outer cover for the first component, an inwardly extending stub axle made integral with the outer cover, an outwardly extending mounting pin also integral with the outer cover, and at least one bearing mounted on the stub axle rotatably supporting the first component.

Preferably, this invention relates to an end cap for an idler roller which is moulded from a polymer material.

The polymer material may be of any appropriate kind and a suitable material is glass-filled nylon.

The end cap may include two or more components. In one embodiment of the invention the end cap includes a first component which is engageable with an idler shell, an inner cover and an outer cover.

The inner cover and the first component may form a seal of any appropriate kind. Similarly the outer cover and the first component may form a seal of any appropriate kind. In each case the seal may comprise a labyrinth seal, a spiral seal or, if necessary, a lip seal.

The spiral seal may include a tongue formation which spirals outwardly from a central position, in a direction which, due to rotation of the end cap which occurs in use, assists in directing a particle contained in the spiral radially outwardly and hence away from the end cap. The tongue formation may be in a stationary part, but preferably is in a rotating part, of the end cap.

The labyrinth seals may be formed by means of interengaging tongue and groove formations.

The tongue and groove formations may be moulded directly into the first component and into the inner and outer covers.

The outer cover may include a mounting pin which may be notched or formed with flats or any other formations to anchor the mounting pin to a suitable support. The mounting pin and stub axle may be co-axial.

The outer cover may include an inwardly extending stub axle on which one or more bearings are mounted and which receive the first component.

If two bearings are used then these are preferably spaced from one another along the inner stub axle to provide a balanced support structure. Alternatively a double bearing may be used to provide a similar function.

The first component may have an outer rim which is engageable with the idler shell, preferably with friction fit, an inner hub in which the bearing or bearings are located, and ribs between the hub and the rum which deform in a controlled manner, when the rim is radially compressed, to maintain the rim centrally and symmetrically positioned relatively to the hub. The ribs may be of any appropriate shape or orientation and may for example be sinuous or V-shaped, or have one or more hollow formations.

The invention also extends to an idler roller which includes a shell and two end caps, each of the aforementioned kind, engaged with opposing ends of the shell.

The shell may be covered with an injection moulded plastics coating of any appropriate kind which is corrosion and wear resistant. The shell may for example be made from metal or plastic.

The shell may contain longitudinal stiffening ribs on its inside.

The invention further extends to a method of assembling an idler roller which includes the steps of engaging two end caps having stub axles with opposing respective ends of an idler shell, placing the assembly in an injection moulding machine, and injection moulding a plastic coating over at least the shell.

The invention also provides an idler roller which includes a shell, end caps engaged with opposed ends of the shell, and a plastic coating which is injection moulded directly over at least the shell.

Brief Description of the Drawings

Preferred embodiments of the invention are described below by way of example, with reference to the accompanying drawings.

Figure 1 is a side view in section of an end of an idler roller according to one form of the invention. Figure 2 is a perspective view, again sectioned, of an end cap shown in Figure 1.

Figure 3 is a schematic view of an inner side of an end cap with different rib supports.

Figure 4 illustrates a spiral seal which can be included in the end cap of the invention.

Figure 5 is a side view of the idler roller as shown in Figure 1 but with certain modifications made thereto.

Figures 6 and 7 are cross sectional views of alternative embodiments of a shell for the idler roller.

Detailed Description of the Drawings

Figure 1 of the accompanying drawings illustrates an end of an idler roller (10) according to the invention which includes a shell (12), plastic coating (14) over the shell and, at opposite ends of the shell (12), two end caps (16). Only one end cap is illustrated in the drawing.

Each end cap includes a first component ( 18 ) which is directly engaged with the shell (12), an outer cover (20) and an inner cover ( 22 ) .

The first component ( 18 ) , the outer cover ( 20 ) and the inner cover (22) are each moulded from a suitable polymer material such as glass-filled nylon.

The first component (18), and outer cover (20) are formed with interengaging circular tongue and groove formations ( 24 ) which define an integral moulded labyrinth seal. Similarly the first component (18) and the inner cover (22) are formed with tongue and groove formations (26) which form an inner labyrinth seal. If necessary, although this will be at the increase of frictional wear and drag a lip seal ( 60 ) as shown in Figure 5 could be formed across an exposed gap ( 28 ) between the component ( 18 ) and the end cap (24), or across an exposed gap (30) between the first component(18) and the inner cover (22).

The outer cover (20) is formed with an outwardly extending pin (32) which has flats (34), more clearly shown in Figure 2, to facilitate its non-rotational engagement with an appropriate support structure, not shown.

An inwardly extending stub axle (36), which is integral with the outer cover, extends through the first component (18). The outwardly extending pin (32) and stub axle (36) are co-axial with each other. Two bearings (38) and (40) are mounted on the stub axle (36) and provide rotational support for the first component (18). The inner cover (22) is kept in position by means of a circlip, not shown, which is engaged with a groove (39) in the stub axle, adjacent an outer side of the inner cover (22).

The shell (12) is initially engaged with two of the end caps (16) and thereafter the shell and end caps are placed in an injection moulding machine, not shown. The plastic coating (14), of a suitable wear and corrosion resistant material, is then directly injection moulded at least over the shell (12) in conventional manner. Provided the end caps are correctly and centrally positioned the coating ( 14 ) is symmetrically formed on the shell ( 12 ) and no further finishing or machining of the coating is required.

It is to be noted that the injection moulding technique described hereinbefore does not necessarily require end caps of the kind shown in Figures 1 and 2 in order to be implemented. Thus the scope of the invention in this respect is not confined in any way.

The use of the end caps shown in Figures 1 and 2 means that an idler roller can be constructed from fewer parts. This lowers costs and facilitates assembly. The moulded polymer parts have the following advantages when compared to an end cap which is fabricated from steel; there is greater design freedom; the parts are moulded exactly to the required size and no further finishing is required; the accurate moulding results in good tolerance and quality control and produces a free running precision idler roller; the idler roller has good corrosion resistance; there is no need for painting or any other finishing once the end caps are engaged with the shell subject of course to the optional coating (14) being applied to the shell; the bearings (38) and (40) are precisely supported; the seals which are provided by the labyrinth formations are automatically formed and this results in longer idler roller life; where use is made of two spaced bearings a cantilever type support is provided which reduces stresses; and there is a substantial saving in weight which makes installation easier and reduces transport costs.

Another benefit is that it is not necessary to have a shaft extending through the shell of an idler roller which incorporates end caps of the kind described. The stub axles protruding from the end caps are all that is necessary to support the idler roller adequately. The elimination of the shaft saves weight, facilitates manufacture and assists in providing a more effective seal for the bearings.

The first component (18) includes an outer rim (42) which is engaged with an interference fit directly with an inner surface of the shell (12), and an inner hub (44) in which the bearings (38) and (40) are located. As shown more clearly in Figure 3 a number of ribs (46) extend in a general radial direction from the hub (44) and connect the hub ( 44 ) to the rim ( 42 ) . Hollow formations ( 48 ) , between the ribs, face the interior of the shell. A section (50) of the first component (18), on an opposing side, interconnects the ribs ( 46 ) . The tongue and groove formations, which make up the labyrinth seal ( 24 ) , are formed in this section ( 50) . Figure 3 is a somewhat schematic end view of the end cap, in the direction marked "3" shown in Figure 1. This figure depicts different types of ribs (46A), (46B), (46C) and (46D) between the hub and the rim.

The tolerances of the inner diameter of the shell (12) and the outer diameter of the rim (42) must be such that the rim is frictionally retained in position when it is inserted into the shell. These components are therefore made under precision conditions but, nonetheless, it is possible for the rim (42) to be oversized relatively to the inner surface of the shell. When the rim is pressed into position it is radially compressed and radial deformation of the end cap takes place.

It has been found that a rib (46A) of the kind shown in Figure 3 does not necessarily reform symmetrically with the result that the stub axle may be position off-centre relatively to the shell. It is desirable, in this regard, for the ribs to have a shape which permits symmetrical radial deformation under the conditions described.

The ribs (46) may therefore be of the kind (46B), (46C) or (46D) shown in Figure 3, or any equivalent shape which permits radial deformation. Tests have shown that the rib (46C) may be the preferred option.

The rib (46B) includes a central hollow formation (52) which provides a volume which is capable of absorbing radial deformation in a symmetrical manner. The ribs (46C) and (46D) on the other hand deflect evenly when loaded in the radial direction. The type of rib which is chosen, its dimensions and the number of ribs between the hub and the rim are chosen taking into account, inter alia, the need for a firm frictional engagement between the rim (42) and the shell (12) and the ability of the end cap to deform symmetrically radially if an oversized condition should arise. Figure 4 is a side view of the section ( 50 ) and illustrates a modified form of sealing arrangement for use in the end cap. In this case use is made of a labyrinth seal which is not as extensive as the labyrinth seal (24) shown in Figure 1 but which is formed in an analogous manner by means of interengaging tongue and groove formations (54A) and ( 54B) respectively. Outwardly extending radial tongue formations (56) are located in a corresponding groove formation (not shown) in the outer cover ( 20) . The tongue formation ( 56 ) spiral outwardly from the labyrinth seal in a direction which is related to the direction of rotation of the roller. Thus, viewed from the side, if the roller rotates in a first direction (58) about its axis then the tongue formations ( 56 ) move radially away from the axis as rotation takes place. This has the effect that any dirt particle which comes into contact with either tongue formation is moved outwardly by centrifugal force as the roller rotates and is urged towards the gap ( 28 ) . This assists in keeping foreign material from reaching the bearings (38) and (40).

A similar radial seal can be provided, if necessary, between the first component (18) and the inner cover (22).

In Figures 6 and 7 are shown cross sectional views of alternative shells (70) and (71). The shell (70) is made from a plastics material and has a number of equally spaced longitudinal stiffening ribs (72) on its inside. At their innermost ends the ribs (72 ) end in a co-axial tube ( 73) . The ribs (74) of the embodiment shown in Figure 7 extend only a small distance toward the centre of the shell and are not interconnected at this innermost ends. These shells are more rigid and reduce the amount of material required.

Claims

CLMMS

1. An idler roller comprising an idler shell, a stub axle at each end of the idler shell and at least one bearing located on each stub axle rotatably supporting the idler shell.

2. An idler roller according to claim 1, comprising an end cap at each end of the idler shell, each of said end caps having a first component which is engageable with the idler shell, an inner cover and an outer cover for the first component, an inwardly extending stub axle made integral with the outer cover, an outwardly extending mounting pin also integral with the outer cover, and at least one bearing mounted on the stub axle rotatably supporting the first component.

3. An end cap for an idler roller having an idler shell, the end cap comprising a first component which is engageable with the idler shell, an inner cover and an outer cover for the first component, an inwardly extending stub axle made integral with the outer cover, an outwardly extending mounting pin also integral with the outer cover, and at least one bearing mounted on the stub axle rotatably supporting the first component.

4. An idler roller as claimed in claim 2 or an end cap as claimed in claim 3 in which the mounting pins and stub axles are co-axial.

5. An idler roller as claimed in claim 2 or 4, or an end cap as claimed in claim 3 or 4, in which the inner cover and the first component and/or the outer cover and the first component comprises seals between them.

6. An idler roller or end cap as claimed in claim 5 in which the seals comprise labyrinth seals.

7. An idler roller or end cap as claimed in claim 5 or 6 in which the seals comprise spiral seals.

8. An idler roller or end cap as claimed in claim 5, 6 or 7 in which the seals comprise lip seals.

9. An idler roller or end cap as claimed in claim 7, or claim 8 when dependant on claim 7, in which the spiral seals include tongue formations which spiral radially outwardly from a central position, in a direction which, due to rotation of the end cap which occurs in use, assists in directing a particle contained in the spiral outwardly.

10. An idler roller as claimed in any of claims 1, 2 or 4 to 9, or an end cap as claimed in any of claims 3 to 9, in which there are two bearings on each stub axle, said bearings being spaced from one another along the stub axle to provide a balanced support structure.

11. An idler roller as claimed in any of claims 2 or 4 to

10 or an end cap as claimed in any of claims 3 to 10 in which the mounting pin is notched or formed with flats to anchor the mounting pin to a suitable support structure.

12. An idler roller as claimed in any of claims 2 or 4 to

11 or an end cap as claimed in any of claims 3 to 11, in which the first component has an outer rim, an inner hub in which the bearing or bearings are located, and ribs between the hub and the rim which deform in a controlled manner, when the rim is radially compressed, to maintain the rim centrally and symmetrically positioned relatively to the hub.

13. An idler roller or end cap as claimed in claim 12, in which the ribs are of sinuous shape.

14. An idler roller as claimed in claims 12 or 13 in which the first component has an outer rim which is engageable by means of a friction fit with the idler shell. j

15. An idler roller as claimed in any of claims 1, 2 or 4 to 14 in which the shell is covered with an injection moulded plastics coating which is corrosion and wear resistant.

16. An idler roller as claimed in any of claims 1, 2 or 4 to 15 in which the shell contains stiffening ribs on its inside.

17. A method of assembling an idler roller which includes the steps of engaging two end caps having stub axles with opposing respective ends of an idler shell, placing the assembly in an injection moulding machine, and injection moulding a plastic coating over at least the shell.

18. An idler roller according to any of claims 2 or 4 to 16 or an end cap according to any of claims 3 to 13, in which the end cap is moulded from a polymer material.

19. An idler roller or an end cap according to claim 18, in which the polymer material is glass-filled nylon.

20. An idler roller substantially as described herein with reference to and/or as illustrated in Figures 1 to 7.

21. An end cap for an idler roller substantially as described herein with reference to and/or as illustrated in Figures 1 to 5.

22. A method of assembling an idler roller substantially as described herein with reference to Figures 1 to 7.